A temperature sensing patch that is easy to use and capable of efficiently monitoring temperature change in human, body for a long time, capable of being used with a reading device, comprising the temperature sensing patch configured to attach to human skin, comprising a housing, a circuit board, a temperature sensing unit electrically connected with the circuit board, a battery, a processor chip, at least a memory unit, and at least a port; wherein the processor chip can automatically turn on the temperature sensing patch and reset the previous data by a predetermined program, rather than through a manual switch, when the temperature sensing patch is removed from the reading device.

Pocket-size folding device with integrated electrodes for recording, processing and transmission with three ECG leads is a hand held ECG device with integrated electrodes used to measure, process and transmit three ECG leads to the remote diagnostic center. When in closed position and not in use the device is more compact and robust so it can be carried in a pocket or a pouch while electrodes are protected from getting dirty or damaged When opening it into a measuring position it becomes ergonomic. It is well adapted to the shape of a user's chest which ensures stable and reliable contact between chest electrodes (4-6) and chest surface. Finger electrodes (7,8) are designed for a contact with left hand and right hand thumbs as well as supporting the device and ensuring sufficient pressure to the chest without intense use of user's arms. The device is compact, it doesn't use cables or levers which makes it very easy to use.

The present invention provides a removable optical imaging device cap for use with a near infrared (NIR) light optical imaging device for detecting intracranial hematoma.

A system and method for performing a radiofrequency (RF) ablation procedure with a cooled RF probe includes measuring one or more local perfusion characteristics at an ablation site within a patient. The method also includes determining a heat transfer due to local perfusion at the ablation site based on the one or more local perfusion characteristics. Further, the method includes determining an operating threshold for the cooled RF probe based, at least in part, on the heat transfer. Moreover, the method includes controlling the cooled RF probe based on the operating threshold to create a lesion at the ablation site within the patient.

Pre-connected analyte sensors are provided. A pre-connected analyte sensor includes a sensor carrier attached to an analyte sensor. The sensor carrier includes a substrate configured for mechanical coupling of the sensor to testing, calibration, or wearable equipment. The sensor carrier also includes conductive contacts for electrically coupling sensor electrodes to the testing, calibration, or wearable equipment.

There is provided a device and a method of operating the device for determining whether the device is immersed in a fluid. An acceleration signal for the device is acquired (302) and a pressure within the device is detected (304). It is determined whether the device is immersed in a fluid based on a comparison of the acquired acceleration signal with the detected pressure (306).

A sensor assembly (256) for detecting at least one analyte in a body fluid and a method of assembly a sensor assembly (256) for detecting at least one analyte in a body fluid are disclosed. The sensor assembly (256) comprises: at least one body mount (212) configured for attachment to a body of a user; at least one electronics unit (186) attachable to the body mount (212), having at least one electronics component (208) for one or more of controlling the detection of the analyte or transmitting measurement data to another component;
wherein the body mount (212) includes a locking mechanism (216) having at least one lever (218) pivotably mounted to the body mount (212), the lever (218) being configured to lock the electronics unit (186) to the body mount (212).

A physiological characteristic sensor system includes a physiological characteristic sensor. The physiological characteristic sensor includes a housing having a first housing portion coupled to a second housing portion, and an antenna coupled to the first housing portion. The physiological characteristic sensor system includes a sensor inserter configured to be coupled to the physiological characteristic sensor. The sensor inserter includes a sensor retainer, and the sensor retainer is configured to couple to the second housing portion in a second state to couple the physiological characteristic sensor to the sensor inserter.

An optoacoustic probe including an ultrasound transducer array, an acoustic lens and a light path separated from the transducer array by an isolator to mitigate light energy from the light path from reaching the transducer array. The isolator being formed from a mixture including a flexible carrier, a coloring and between 10% and 80% by volume micro-bubbles. The isolator mixture being adapted to both absorb light energy and the optoacoustic response to light energy. In an embodiment, an optoacoustic probe also comprises an optical window and/or a diffuser, and the isolator also separating the transducer array from these components.

A radiographic imaging apparatus includes a sensor substrate including a flexible base material, and an active area which is provided on a first surface of the base material and in which a plurality of pixels, which accumulate electrical charges generated in accordance with light converted from radiation, are formed; a conversion layer that is provided on the first surface side in the sensor substrate to convert radiation into the light; and a grid that is disposed on a second surface side opposite to the first surface of the base material and has a removal portion that has a mesh-like radiation absorbing member provided between a plurality of partitions in units of a predetermined number of pixels to remove scattered radiation according to the radiation.